Project description:Identifying strategies to improve the efficacy of immune checkpoint blockade (ICB) remains a major clinical need. Here, we show that therapeutically targeting the COX-2/PGE2/EP2-4 pathway with widely used non-steroidal and steroidal anti-inflammatory drugs synergized with ICB in mouse cancer models. We exploited a bilateral surgery model to harness the heterogeneity in treatment outcome and distinguish responders from non-responders shortly following treatment. Deep cellular and molecular tumor profiling revealed acute IFN-γ-driven tumor remodeling in responder mice that was also associated with patient benefit to ICB. Crucially, monotherapy with COX-2 inhibitors or EP2-4 PGE2 receptor antagonists rapidly induced this response program and, in combination with ICB, increased the intratumoral accumulation of T cells with enhanced effector function. Inhibition of the COX-2/PGE2 pathway in patient-derived tumor fragments from multiple patients and cancer types revealed a similar shift in the tumor inflammatory environment to favor T cell activation. Our findings establish the COX-2/PGE2/EP2-4 axis as an independent immune checkpoint and a readily translatable strategy to switch the tumor inflammatory profile from cold to hot and enhance the efficacy of immunotherapy.

Project description:The discovery of immune checkpoint inhibitor (ICI) has highlighted the clinical importance of immune evasion in cancer. However, only a fraction of cancer patients show response to ICI, raising a question on immune suppression mechanisms other than immune checkpoint. In this study, we examined the role of the lipid inflammatory mediator PGE2 in immune evasion of the ICI-insensitive Lewis Lung Carcinoma line 1 (LLC1) mouse model. Inhibition of PGE receptors, EP2 and EP4, significantly suppressed tumor growth through the modulation of host immune cells. Single cell RNA-sequencing analysis revealed that EP2/4 inhibition elicited anti-tumor immunity through the reprogramming of inflammatory myeloid cells by downregulating expression of genes in NFB signaling and actions and suppression of the mregDC-regulatory T cell axis by downregulating genes associated with regulatory T cell recruitment and activation. Taken together, our work suggests that PGE2-EP2/EP4 signaling induces proinflammatory myeloid and tolerogenic lymphoid environments in ICI-insensitive tumors, which is amenable to EP2 and EP4 inhibitors..

Project description:Prostaglandins (PGs) are inflammatory mediators. Aspirin-like non-steroidal anti-inflammatory drugs (NSAIDs) inhibit cyclooxygenase (COX), an initiating enzyme of PG biosynthesis1. Daily use of aspirin-like drugs lowers the risk of cancer death not only prophylactically but therapeutically suggesting critical roles of PGs in cancer. However, general mechanisms by which PGs contribute to progression of a wide variety of human cancers remain elusive. Here, using scRNAseq analysis comparing immune cells infiltrating human tumors and a syngeneic mouse tumor, we have dissected this issue. We found that in human tumors, COX is dominantly expressed in infiltrating myeloid cells, and, among PG receptors, PGE receptor EP4 and to a less extent EP2 are expressed in both T cells and myeloid cells. DEG analysis between PTGER4hi and PTGER4lo CD8+ T cells indicates downregulation of IL-2-STAT5 signaling, oxidative phosphorylation, glycolysis and Myc targets in EP4hi CD8+ T cells, as revealed by suppressed expression of IL-2 receptor subunit gene and genes of OXPHOS, glycolytic enzymes and ribosomal proteins (RPs). Similar downregulation of OXPHOS, glycolytic enzymes and RP genes is found in PTGER4hi myeloid cells. Notably, such downregulation of OXPHOS and RP genes was found in immune cells infiltrating LLC1 mouse tumor, and reversed by treatment of tumor-bearing mice with EP2 and EP4 antagonists. In vitro in CD8+ T cells, EP4 is induced upon TCR activation and PGE2 acts on EP4, downregulates Il2ra expression and suppresses expression of Myc and PGC-1, thereby impairing both mitochondria and glycolysis as well as ribosome biogenesis in these cells. Similarly, EP4 is induced upon activation in macrophages and PGE2 downregulates Myc and OXPHOS pathwaysin these cells irrespective of other stimuli. These results demonstrate that PGE2 shapes immunosuppressive tumor microenvironment by hampering bioenergetic metabolism and ribosome biogenesis in infiltrating immune cells via EP4 receptor.

Project description:Prostaglandins (PGs) are inflammatory mediators. Aspirin-like non-steroidal anti-inflammatory drugs (NSAIDs) inhibit cyclooxygenase (COX), an initiating enzyme of PG biosynthesis1. Daily use of aspirin-like drugs lowers the risk of cancer death not only prophylactically but therapeutically suggesting critical roles of PGs in cancer. However, general mechanisms by which PGs contribute to progression of a wide variety of human cancers remain elusive. Here, using scRNAseq analysis comparing immune cells infiltrating human tumors and a syngeneic mouse tumor, we have dissected this issue. We found that in human tumors, COX is dominantly expressed in infiltrating myeloid cells, and, among PG receptors, PGE receptor EP4 and to a less extent EP2 are expressed in both T cells and myeloid cells. DEG analysis between PTGER4hi and PTGER4lo CD8+ T cells indicates downregulation of IL-2-STAT5 signaling, oxidative phosphorylation, glycolysis and Myc targets in EP4hi CD8+ T cells, as revealed by suppressed expression of IL-2 receptor subunit gene and genes of OXPHOS, glycolytic enzymes and ribosomal proteins (RPs). Similar downregulation of OXPHOS, glycolytic enzymes and RP genes is found in PTGER4hi myeloid cells. Notably, such downregulation of OXPHOS and RP genes was found in immune cells infiltrating LLC1 mouse tumor, and reversed by treatment of tumor-bearing mice with EP2 and EP4 antagonists. In vitro in CD8+ T cells, EP4 is induced upon TCR activation and PGE2 acts on EP4, downregulates Il2ra expression and suppresses expression of Myc and PGC-1, thereby impairing both mitochondria and glycolysis as well as ribosome biogenesis in these cells. Similarly, EP4 is induced upon activation in macrophages and PGE2 downregulates Myc and OXPHOS pathwaysin these cells irrespective of other stimuli. These results demonstrate that PGE2 shapes immunosuppressive tumor microenvironment by hampering bioenergetic metabolism and ribosome biogenesis in infiltrating immune cells via EP4 receptor.

Project description:While the role of prostaglandin E2 (PGE2) in promoting malignant progression is well-established, how to optimally block the activity of PGE2 signaling remains to be demonstrated. Clinical trials with prostaglandin pathway targeted agents have shown activity but without sufficient significance or dose-limiting toxicities that have prevented approval. PGE2 signals through four receptors (EP1-4) to modulate tumor progression. EP2 and EP4 signaling exacerbates tumor pathology and is immunosuppressive through potentiating cAMP production. EP1 and EP3 signaling has the opposite effect through increasing IP3 and decreasing cAMP. Using available small molecule antagonists of single EP receptors, the COX-2 inhibitor celecoxib, or a novel dual EP2/EP4 antagonist generated in this investigation, we tested which approach to block PGE2 signaling optimally restored immunologic activity in mouse and human immune cells and antitumor activity in syngeneic, spontaneous and xenograft tumor models. We found that dual antagonism of EP2 and EP4 together significantly enhanced the activation of PGE2-suppressed mouse and human monocytes and CD8+ T cells in vitro as compared to single EP antagonists. CD8+ T cell activation was dampened by single EP1 and EP3 antagonists. Dual EP2/EP4 PGE2 receptor antagonists increased TME lymphocyte infiltration and significantly reduced disease burden in multiple tumor models, including in the adenomatous polyposis coli (APC)min+/- spontaneous colorectal tumor model, compared to celecoxib. These results support a hypothesis that redundancy of EP2 and EP4 receptor signaling necessitates a therapeutic strategy of dual blockade of EP2 and EP4. Here we describe TPST-1495, a first-in-class orally available small molecule dual EP2/EP4 antagonist.

Project description:It has long been recognized that there is substantial inter-individual variability in the analgesic efficacy of non-steroidal anti-inflammatory drugs (NSAIDs), but the mechanisms underlying this variability are not well understood. In order to characterize the factors associated with heterogeneity in response to ibuprofen, we performed functional neuroimaging, pharmacokinetic/pharmacodynamic assessments, biochemical assays, and gene expression analysis in twenty-nine healthy subjects who underwent third molar extraction. Subjects were treated with rapid-acting ibuprofen (400 mg; N=19) or placebo (N=10) in a randomized, double-blind design. Compared to placebo, ibuprofen-treated subjects exhibited greater reduction in pain scores, alterations in CBF in brain regions associated with pain processing, and inhibition of ex vivo COX-1 and COX-2 activity and urinary prostaglandin metabolites (p<0.05). Ibuprofen-treated subjects could be stratified into partial responders (N=9, required rescue medication) and complete responders (N=10, no rescue medication). This variability in analgesic efficacy was not associated with demographic/clinical characteristics, markers of systemic inflammation, or ibuprofen pharmacokinetics. Complete responders exhibited less suppression of urinary prostaglandin metabolites and greater induction of serum tumor necrosis factor-α and interleukin 8, compared to partial responders (p<0.05). Partial responders exhibited more alterations in gene expression in peripheral blood mononuclear cells after surgery, with an enrichment in inflammatory pathways. These findings suggest that activation of the prostanoid biosynthetic pathway and regulation of the inflammatory response to surgery differs between partial and complete responders. Future studies are necessary to elucidate the molecular mechanisms underlying this variability and identify biomarkers that are predictive of ibuprofen response.

Project description:Non-inflamed (cold) tumors such as leiomyosarcoma (LMS) do not benefit from immune checkpoint blockade (ICB) monotherapy. Combining ICB with angiogenesis-, or poly-ADP ribose polymerase (PARP) inhibitors may increase tumor immunogenicity by altering the immune cell composition of the tumor microenvironment (TME). The DAPPER phase II study evaluated the safety, immunologic, and clinical activity of ICB-based combinations in pre-treated LMS patients.

Project description:Microglia, the innate immune cells of the central nervous system, perform critical inflammatory and non-inflammatory functions to maintain homeostasis and normal neural function. However in Alzheimer’s disease (AD), these beneficial functions become progressively impaired, contributing to synapse and neuron loss and cognitive impairment. The inflammatory cyclooxygenase-PGE2 pathway, including the PGE2 receptor EP2, is implicated in AD development, both in human epidemiology and in transgenic models of AD. To test the transcriptional responses of EP2-deficient microglia to Aβ in vivo, we used mice in which the EP2 receptor is conditionally deleted in microglia using the CD11b-Cre transgene and floxed alleles of the EP2 gene. By injecting these mice with Aβ ICV and isolating microglia from the brains, we have been able to establish the transcriptional response of microglia to Aβ in vivo and test how EP2 deletion in microglia affects this response.

Project description:Microglia, the innate immune cells of the central nervous system, perform critical inflammatory and non-inflammatory functions to maintain homeostasis and normal neural function. However in Alzheimer’s disease (AD), these beneficial functions become progressively impaired, contributing to synapse and neuron loss and cognitive impairment. The inflammatory cyclooxygenase-PGE2 pathway, including the PGE2 receptor EP2, is implicated in AD development, both in human epidemiology and in transgenic models of AD. To test the transcriptional responses of EP2-deficient microglia to Aβ in vivo, we used mice in which the EP2 receptor is conditionally deleted in microglia using the CD11b-Cre transgene and floxed alleles of the EP2 gene. By injecting these mice with Aβ ICV and isolating microglia from the brains, we have been able to establish the transcriptional response of microglia to Aβ in vivo and test how EP2 deletion in microglia affects this response. 8 month-old C57BL/6 mice, of the genotype CD11b-Cre; EP2+/+ or CD11b-Cre; EP2lox/lox, were injected I.C.V. with either Aβ or vehicle. 48 hours after injection, the mice were sacrificed and transcardially perfused with cold heparinized 0.9% NaCl. Brains were then removed from the mice and pooled, two brains of the same genotype per sample, to ensure adequate cell and RNA yield. The brains were then enzymatically dissociated for microglia isolation using the Neural Tissue Dissociation Kit (P), MACS Separation Columns (LS), and magnetic CD11b Microbeads from Miltenyi Biotec according to the manufacturer's protocol. Immediately after isolating the microglia, RNA was extracted from the cells for microarray analysis.

Project description:Glioblastomas show low response rates to immune checkpoint blockade with few hypermutated glioblastomas showing responses. Moreover, a growing body of evidence suggests that macrophages in the glioblastoma microenvironment impair anti-tumor immunity and immunotherapy approaches. Here, we investigate macrophage-mediated mechanisms of response and resistance to combinatory immune checkpoint blockade targeting PD-1 and CTLA-4 in the murine syngeneic Gl261 glioblastoma model. Nanostring analysis from CD45highCD11b+ cells isolated from ICB responder and non-responder Gl261 tumors was performed. Here, we provide evidence for a differential expression of pro- and anti-inflammatory genes in CD45highCD11b+ cells from ICB responder and non-responder tumors pointing towards a suppressive phenotype of ICB non-responder CD45highCD11b+ cells. Targeting these suppressive CD45highCD11b+ cells in the glioblastoma microvenvironment might thus potentiate ICB efficacy.